c++11实现异步定时器

时间:2023-03-09 17:56:07
c++11实现异步定时器

c++11提供了丰富的时间和线程操作函数,比如 std::this_thread::sleep, std::chrono::seconds等。可以利用这些来很方便的实现一个定时器。 
    定时器要求在固定的时间异步执行一个操作,比如boost库中的boost::asio::deadline_timer,以及MFC中的定时器。这里,利用c++11的thread, mutex, condition_variable 来实现一个定时器: 
    定时器要求异步执行任务    ----> 开辟独立的线程 
    定时器要求能够启动和取消 ----> 提供安全的取消操作,使用互斥量和信号量 
    定时器要求每个定时时刻到达的时候执行的任务要尽可能节省时间

实现

#ifndef TIMER_H_

#define TIMER_H_

#include<functional>

#include<chrono>

#include<thread>

#include<atomic>

#include<memory>

#include<mutex>

#include<condition_variable>

class Timer{

public:

	Timer() :expired_(true), try_to_expire_(false){

	}

	Timer(const Timer& t){

		expired_ = t.expired_.load();

		try_to_expire_ = t.try_to_expire_.load();

	}

	~Timer(){

		Expire();

		//		std::cout << "timer destructed!" << std::endl;

	}

	void StartTimer(int interval, std::function<void()> task){

		if (expired_ == false){

			//			std::cout << "timer is currently running, please expire it first..." << std::endl;

			return;

		}

		expired_ = false;

		std::thread([this, interval, task](){

			while (!try_to_expire_){

				std::this_thread::sleep_for(std::chrono::milliseconds(interval));

				task();

			}

			//			std::cout << "stop task..." << std::endl;

			{

				std::lock_guard<std::mutex> locker(mutex_);

				expired_ = true;

				expired_cond_.notify_one();

			}

		}).detach();

	}

	void Expire(){

		if (expired_){

			return;

		}

		if (try_to_expire_){

			//			std::cout << "timer is trying to expire, please wait..." << std::endl;

			return;

		}

		try_to_expire_ = true;

		{

			std::unique_lock<std::mutex> locker(mutex_);

			expired_cond_.wait(locker, [this]{return expired_ == true; });

			if (expired_ == true){

				//				std::cout << "timer expired!" << std::endl;

				try_to_expire_ = false;

			}

		}

	}

	template<typename callable, class... arguments>

	void SyncWait(int after, callable&& f, arguments&&... args){

		std::function<typename std::result_of<callable(arguments...)>::type()> task

			(std::bind(std::forward<callable>(f), std::forward<arguments>(args)...));

		std::this_thread::sleep_for(std::chrono::milliseconds(after));

		task();

	}

	template<typename callable, class... arguments>

	void AsyncWait(int after, callable&& f, arguments&&... args){

		std::function<typename std::result_of<callable(arguments...)>::type()> task

			(std::bind(std::forward<callable>(f), std::forward<arguments>(args)...));

		std::thread([after, task](){

			std::this_thread::sleep_for(std::chrono::milliseconds(after));

			task();

		}).detach();

	}

private:

	std::atomic<bool> expired_;

	std::atomic<bool> try_to_expire_;

	std::mutex mutex_;

	std::condition_variable expired_cond_;

};

#endif

////////////////////test.cpp

#include<iostream>

#include<string>

#include<memory>

#include"Timer.hpp"

using namespace std;

void EchoFunc(std::string&& s){

	std::cout << "test : " << s << endl;

}

int main(){

	Timer t;

	//周期性执行定时任务

	t.StartTimer(1000, std::bind(EchoFunc,"hello world!"));

	std::this_thread::sleep_for(std::chrono::seconds(4));

	std::cout << "try to expire timer!" << std::endl;

	t.Expire();

	//周期性执行定时任务

	t.StartTimer(1000, std::bind(EchoFunc,  "hello c++11!"));

	std::this_thread::sleep_for(std::chrono::seconds(4));

	std::cout << "try to expire timer!" << std::endl;

	t.Expire();

	std::this_thread::sleep_for(std::chrono::seconds(2));

	//只执行一次定时任务

	//同步

	t.SyncWait(1000, EchoFunc, "hello world!");

	//异步

	t.AsyncWait(1000, EchoFunc, "hello c++11!");

	std::this_thread::sleep_for(std::chrono::seconds(2));

	return 0;

}

相关文章